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Experimenting with Parallel Programming Models on a Shallow Water Proxy Application

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SWE-PPM

Parallel implementations of Shallow Water Equations based on the teaching code(https://github.com/TUM-I5/SWE).

Documentation

The documentation is available in the Wiki

System Requirements

Getting SWE-PPM

  1. Clone the repository with following command:
    git clone --recursive
  2. Checkout the sc_paw-atm_workshop :
    git checkout tags/sc_paw-atm_workshop -b master

Installation

  1. Create build directory
    mkdir build && cd build
  2. Set necessary environment variables
    UPC++:
    export UPCXX_PATH=\path\to\upcxx
    Chameleon:
    export CHAMELEON_PATH=\path\to\chameleon HPX:
    export HPX_PATH=\path\to\hpx\
  3. Specify cmake targets and compile options
    cmake -DBUILD_SWE_MPIOVERDECOMP=On\ -DBUILD_SWE_MPIOVERDECOMPTASKING=On\ \-DBUILD_SWE_MPI=On \-DBUILD_SWE_UPCXX=On \-DBUILD_SWE_CHAMELEON=On \-DBUILD_SWE_HPX=On ..
    For a complete list of configurable options call
    cmake -LAH ..
  4. Compile targets
    make or cmake --build . --target swe_benchmark_<target>

Charm++ Installation

Unfortunately Charm++ still requires the old scons build system.

  1. Set environment variable
    export CHARM_PATH=\path\to\charm
  2. Compile using scons
    scons writeNetCDF=True compiler=intel solver=hybrid openmp=false parallelization=charm asagi=false copyenv=true vectorize=true

Execution

Note, that the below provided examples may vary depending on the system architecture and configuration of the frameworks. The examples execute the compiled scenario with a 2048x2048 cell resolution,80 seconds simulation duration, 20 checkpoints, global time stepping and file output enabled.

  • MPI:
    mpirun -np 56 ./build/swe_benchmark_mpi --simulation-duration 80 --checkpoint-count 20 --resolution-horizontal 2048 --resolution-vertical 2048 --output-basepath ./output/mpi_gts --local-timestepping 0 --write 1
  • UPC++:
    $UPCXX_PATH/bin/upcxx-run -np 56 ./build/swe_benchmark_upcxx --simulation-duration 80 --checkpoint-count 20 --resolution-horizontal 2048 --resolution-vertical 2048 --output-basepath ./output/upcxx_gts --local-timestepping 0 --write 1
  • Charm++:
    $CHARM_PATH/bin/charmrun +p56 ./build/SWE_intel_release_charm_hybrid_vec --simulation-duration 80 --checkpoint-count 20 --resolution-horizontal 2048 --resolution-vertical 2048 --output-basepath ./output/charm_gts --local-timestepping 0 --write 1 --chares 56
  • Chameleon:
    I_MPI_PIN=1 I_MPI_PIN_DOMAIN=auto OMP_NUM_THREADS=27 OMP_PLACES=cores OMP_PROC_BIND=close mpirun -np 56 ./build/swe_benchmark_upcxx --simulation-duration 80 --checkpoint-count 20 --resolution-horizontal 2048 --resolution-vertical 2048 --output-basepath ./output/chameleon_gts --local-timestepping 0 --write 1 --blocks 28
  • HPX:
    mpirun -np 56 ./build/swe_benchmark_hpx --simulation-duration 80 --checkpoint-count 20 --resolution-horizontal 2048 --resolution-vertical 2048 --output-basepath ./output/hpx_gts --local-timestepping 0 --write 1 --blocks 28

More examples of execution scripts can be found at https://github.com/TUM-I5/SWE-PPM/tree/master/jobs

Contributors

  • Michael Bader
  • Martin Bogusz
  • Philipp Samfaß
  • Alexander Pöppl

License

SWE is release unter GPLv3 (see gpl.txt)